Original papers
1. Suzuki, Y., Oishi, M., Hirota, S., Hayashi, H., Haga, S., Koike, S., and Kobayashi, Y. 2025. Developmental changes in the capacity for mucosal immunoglobulin production and secretion in the intestines of growing calves. Veterinay Research, 56: 220.
2. Nishihara, K., Suzuki, Y., Haga, S., and Roh, S. 2024. TLR5 ligand induces the gene expression of antimicrobial peptides and CXCL8 through IL-1β gene expression in cultured rumen epithelial cells. Animal Science Journal, 95: e13972.
3. Yamada, K., Iwamae, K., Suzuki, Y., Koike, S., Kobayashi, Y. 2023. Batch culture analysis to identify potent organic acids for suppressing ruminal methane production. Animal Science Journal, 94: e13873.
4. Shikida, R., Kim, M., Futohashi, M., Nishihara, K., Lee, H., Suzuki, Y., Baek, Y., Masaki, T., Ikuta, K., Iwamoto, E., Uemoto, Y., Haga, S., Terada, F., and Roh, S. 2023. Physiological roles and regulation of hepatic angiopoietin-like protein 3 in Japanese Black cattle (Bos taurus) during the fattening period. Journal of Animal Science, 101: 1-12
5. Yamada, H., Miura, H., Suzuki, Y., Koike, S., Shimamoto, S., Kobayashi, Y. 2023. In vitro effects of cellulose acetate on fermentation profiles, the microbiome, and gamma-aminobutyric acid production in human stool cultures. Current Microbiology, 80; 284
6. Haga, S., Suzuki, Y., Miwa, M., Kubota, K., and Sakatani, M. 2022. Changes in immunoglobulin A and immunoglobulin G concentrations in the saliva of Japanese Black beef cows during calving: a pilot study. Animal Science Journal, 93: e1379.
7. Suzuki, Y., Kubota, K., Haga, S., Hayashi, H., Oishi, M., Miura, H., Roh, S., Koike, S., and Kobayashi, Y. 2022. Expression of chemerin in intestinal mucosa of calves with comparable expression level with other antimicrobial proteins. Animal Science Journal 93: e13750.
8. Kodithuwakku, H., Maruyama, D., Owada, H., Watabe, Y., Miura, H., Suzuki, Y., Hirano, K., Kobayashi, Y., and Koike, S. 2022. Alterations in rumen microbiota via oral fiber administration during early life in dairy cows. Scientific Reports, 12:10798.
9. Miura, H., Takeda, M., Yamaguchi, M., Ohtani, Y., Endo, G., Masuda, Y., Ito, K., Nagura, Y., Iwashita, K., Mitani, T., Suzuki, Y., Kobayashi, Y., and Koike, S. 2022. Application of MinION Amplicon Sequencing to Buccal Swab Samples for Improving Resolution and Throughput of Rumen Microbiota Analysis. Frontiers in Microbiology 13: 783058
10. Hosokawa, M., Hikita, C., Suzuki, Y., Koike, S., and Kobayashi, Y. 2022. Effects of cashew nut shell liquid on hindgut fermentation and microbiota of chickens. Journal of Animal Science and Research 6: 1-8
11. Suzuki, Y., Chiba, S., Nishihara, K., Hagino, A., Kim, W., Lee, H., Nochi, T., Suzuki, T., and Roh, S. 2021. Chemerin regulates epithelial barrier function of mammary glands in dairy cows. Animals 11: 3194
12. Kodithuwakku, K., Owada, H., Miura, H., Maruyama, D., Hirano, K., Suzuki, Y., Kobayashi, Y., and Koike, S. 2021. Effects of oral administration of timothy hay and psyllium on the growth performance and fecal microbiota of preweaning calves. Journal of Dairy Science 104: 12472–12485
13. Narabe, C., Kamiyama, S., Saito, M., Boonsaen, P., Khongpradit, A., Sawanon, S., Suzuki, Y., Koike, S., and Kobayashi, Y. 2021. Cashew nut shell liquid potentially mitigates methane emission from the feces of Thai native ruminant livestock by modifying fecal microbiota. Animal Science Journal 92: e13614
14. Shintani, R., Oh, S., Suzuki, Y., Koike, S., and Kobayashi, Y. 2021. Addition of ginkgo fruit to cattle feces and slurry suppresses methane production by altering the microbial community structure. Animal Science Journal 92: e13620
15. Neves, A. L. A., Yu, J., Suzuki, Y., Baez-Magana, M., Arutyunova, E., O'Hara, E., McAllister, T., Ominski, K. H., Lemieux, M. J., and Guan, L. 2021. Accelerated discovery of novel glycoside hydrolases using targeted functional profiling and selective pressure on the rumen microbiome. Microbiome 9: 229
16. Miura, H., Hashimoto, T., Kawanishi, Y., Kawauchi, H., Inoue, R., Shoji, N., Saito, K., Sekiya, M., Saito, Y., Yasuda, J., Yonezawa, C., Endo, T., Kasuya, H., Suzuki, Y., Kobayashi, Y., and Koike, S. 2021. Identification of the core rumen bacterial taxa and their population dynamics during the fattening period in Japanese Black cattle. Animal Science Journal 92: e13601
17. Miura, H., Mukai, K., Sudo, K., Haga, S., Suzuki, Y., Kobayashi, Y., and Koike, S. 2021. Effect of trehalose supplementation in milk replacer on the incidence of diarrhea and fecal microbiota in preweaned calves. Journal of Animal Science 99: 1-9
18. Yamada, H., Watabe, Y., Suzuki, Y., Koike, S., Shimamoto, S., and Kobayashi, Y. 2021. Chemical and microbial characterization for fermentation of water‐soluble cellulose acetate in human stool cultures. Journal of the Science of Food and Agriculture 101: 2950–2960
19. Khongpradit, A., Boonsaen, P., Homwong, N., Suzuki, Y., Koike, S., Sawanon, S., and Kobayashi, Y. 2020. Effect of pineapple stem starch feeding on rumen microbial fermentation, blood lipid profile, and growth performance of fattening cattle. Animal Science Journal 91: e13459
20. Hromádková, J., Suzuki, Y., Pletts, S., Pyo, J., Ma, T., Chen, Y., Steele, M., and Guan, L. 2020. Effect of colostrum feeding strategies on the expression of neuroendocrine genes and active gut mucosa-attached bacterial populations in neonatal calves. Journal of Dairy Science 103: 8629-8642 (Hromádková, J. and Suzuki, Y. equally contributed to this work)
21. Nishihara, K., Suzuki, Y., and Roh, S. Ruminal epithelial insulin-like growth factor-binding proteins 2, 3, and 6 are associated with epithelial cell proliferation. 2020. Animal Science Journal 91: e13422
22. Konda, S., Onodera, R., Kanchanasatit, E., Boonsaen, P., Sawanon, S., Nagashima, K., Suzuki, Y., Koike, S., and Kobayashi, Y. 2019. Effect of cashew nut shell liquid feeding on fermentation and microbiota in the rumen of Thai native cattle and swamp buffaloes. Livestock Science 226: 99-106
23. Nishihara, K., Suzuki, Y., Kim, D., Roh, S. 2019. Growth of rumen papillae in weaned calves is associated with lower expression of insulin-like growth factor-binding proteins 2, 3, and 6. Animal Science Journal 90: 1287-1292
24. Yamano, H., Ichimura, Y., Sawabe, Y., Koike, S., Suzuki, Y., and Kobayashi, Y. 2019. Seasonal differences in rumen bacterial flora of wild Hokkaido sika deer and partial characterization of an unknown bacterial group possibly involved in fiber digestion in winter. Animal Science Journal 90: 790-798
25. Matsuba, K., Padlom, A., Khongparadit, A., Boonsaen, P., Thirawong, P., Sawanon, S., Suzuki, Y., Koike, S., and Kobayashi, Y. 2019. Selection of plant oil as a supplemental energy source by monitoring rumen profiles and its dietary application in Thai crossbred beef cattle. Asian-Australasian Journal of Animal Sciences 32: 1511-1520
26. Watabe, Y., Suzuki, Y., Koike, S., Shimamoto, S., and Kobayashi, Y. 2018. Cellulose acetate, a new candidate feed supplement for ruminant animals: In vitro evaluations. Journal of Dairy Science 101:10929-10938
27. Kang, S., Suzuki, R., Suzuki, Y., Koike, S., Nagashima, K. and Kobayashi, Y. 2018. Rumen responses to dietary supplementation with cashew nut shell liquid and its cessation in sheep. Animal Science Journal 89: 1549-1555
28. Nakano, M., Suzuki, Y., Haga, S., Yamauchi, E., Kim, D., Nishihara, K., Gotoh, T., Nakajima, K., Park, S., Baik, M., Katoh, K., and Roh, S. 2018. Downregulated Angiopoietin-like Peptide 8 Production at Calving Related to Changes in Lipid Metabolism in Dairy Cows. Journal of Animal Science 96: 2646-2658 (Nakano, M. and Suzuki, Y. equally contributed to this work)
29. Nishihara, K., Kato, D., Suzuki, Y., Kim, D., Nakano, M., Yajima, Y., Haga, S., Nakano, M., Ishizaki, H., Kawahara-Miki, R., Kono, T., Katoh, K., and Roh, S. 2018. Comparative transcriptome analysis of rumen papillae in suckling and weaned Japanese Black calves using RNA sequencing. Journal Animal Science 96: 2226-2237
30. Boonsaen, P., Kinjo, M., Sawanon, S., Suzuki, Y., Koike, S., and Kobayashi, Y. 2018. Partial characterization of phylogeny, ecology and function of the fibrolytic bacterium Ruminococcus flavefaciens OS14, newly isolated from the rumen of swamp buffalo. Animal Science Journal 89: 377-385
31. Nishihara, K., Kobayashi, R., Suzuki, Y., Sato, K., Katoh, K., and Roh, S. 2017. Post-prandial decrease in plasma growth hormone levels is not related to the increase in plasma insulin levels in goats. Asian-Australasian Journal of Animal Sciences 30: 1696-1701
32. Oh, S., Suzuki, Y., Hayashi. S., Suzuki, Y., Koike, S., and Kobayashi, Y. 2017. Potency of cashew nut shell liquid in rumen modulation under different dietary conditions and indication of its surfactant action against rumen bacteria. Journal of Animal Science and Technology 59: 27
33. Takahashi, H., Suzuki, Y., Gotoh, T., Mohamed, J., and Alway, S. 2017. Epigallocatechin-3-gallate increases autophagy signaling in resting and unloaded plantaris muscles but selectively suppresses autophagy protein abundance in reloaded muscles of aged rats. Experimental Gerontology 92: 56-66
34. Kato, D., Suzuki, Y., Haga, S., So, K., Yamauchi, E., Nakano, M., Ishizaki, H., Choi, K., Katoh, K., and Roh, S. 2016. Utilization of digital differential display to identify differentially expressed genes related to rumen development. Animal Science Journal 87: 584-590 (Kato, D. and Suzuki, Y. equally contributed to this work)
35. Suzuki, Y., Haga, S., Nakano, M., Ishizaki, H., Nakano, M., Song, S., Katoh, K., and Roh, S. 2016. Post-weaning changes in the expression of chemerin and its receptors in calves are associated with the modification of glucose metabolism. Journal of Animal Science 94: 4600-4610
36. So, K., Suzuki, Y., Yonekura, S., Suzuki, Y., Lee, C., Kim, S., Katoh, K., and Roh, S. 2015. Soluble extract of soybean fermented with Aspergillus oryzae GB107 inhibits fat accumulation in cultured 3T3-L1 adipocyte. Nutrition Research and Practice 9: 439-444
37. Suzuki, Y., Haga, S., Katoh, D., So, K., Choi, K., Jung, U., Lee, H., Katoh, K., and Roh, S. 2015. Chemerin is a novel regulator of lactogenesis in bovine mammary epithelial cells. Biochemical and Biophysical Research Communications 466: 283-288 (Suzuki, Y. and Haga, S. equally contributed to this work)
38. Yamauchi, E., Suzuki, Y., So, K., Suzuki, K., Katoh, K., and Roh, S. 2015. Single Nucleotide Polymorphism in the Coding Region of Bovine Chemerin Gene and Their Associations with Carcass Traits in Japanese Black Cattle. Australasian Journal of Animal Sciences 28: 1084–1089
39. Yi, K., So, K., Hata, Y., Suzuki, Y., Katoh, D., Watanabe, K., Aso, H., Kasahara, Y., Nishimori, K., Chen, C., Katoh, K., and Roh, S. 2015. The regulation of oxytocin receptor gene expression during adipogenesis. Journal of Neuroendocrinology 27: 335-342
40. Hiradate, Y., Inoue, H., Kobayashi, N., Shirakata, Y., Suzuki, Y., Gotoh, A., Roh, S., Uchida, T., Katoh, K., Yoshida, M., Sato, E., and Tanemura, K. 2014. Neurotensin Enhances Sperm Capacitation and Acrosome Reaction in Mice. Biology of Reproduction 91: 53
41. Suzuki, Y., Hong, Y., Song, S., Ardiyanti, A., Kato, D., So, K., Katoh, K., and Roh, S. 2012. The regulation of chemerin and CMKLR1 genes expression by TNF-α, adiponectin and chemerin analog in bovine differentiated adipocytes. Asian-Australasian Journal of Animal Sciences 25: 1316-1321
42. Suzuki, Y., Song, S., Sato, K., So, K., Ardiyanti, A., Kitayama, S., Hong, Y., Lee, S., Choi, K., Hagino, A., Katoh, K., and Roh, S. 2012. Chemerin analog regulates energy metabolism in sheep. Animal Science Journal. 83: 263-267
Reviews
1. Ma, T., Suzuki, Y., Guan, L. 2018. Dissect the mode of action of probiotics in affecting host-microbial interactions and immunity in food producing animals. Veterinary Immunology and Immunopathology 205: 35-48
2. Roh, S., Suzuki, Y., Gotoh, T., Tatsumi, R., Katoh, K. 2016. Physiological Roles of Adipokines, Hepatokines, and Myokines in Ruminants. Asian-Australasian Journal of Animal Sciences 29:1-15 (All authors equally contributed to this work)
Domestic journal
1. 芳賀 聡,中野 美和,宮地 慎,石崎 宏,松山 裕城,鈴木 裕,北山 峻,小林 洋介,加藤 和雄,盧 尚建.2017. ウシ組織におけるα-トコフェロール体内動態関連遺伝子の発現特性に関する研究.栄養生理研究会報 61(1): 9-19
2. Myint, H., Kishi, H., Iwahashi, Y., Suzuki, Y., Koike, S., and Kobayashi, Y. 2017. Bean husk, an agricultural by-product having functionality in animal nutrition and health. 栄養生理研究会報 61(2): 13-19
3. Oh, S., Suzuki Y., Koike, S., and Kobayashi, Y. 2017. Potency of ginkgo fruit for modulation of rumen microbiota and fermentation. 栄養生理研究会報 61(2): 33-41
4. 盧 尚建,加藤 大地,鈴木 裕,芳賀 聡.2016.離乳前後の仔牛のルーメン絨毛上皮組織における遺伝子発現量の比較.栄養生理研究会報 60(2): 79-84
5. 横山 次郎,蘇 敬夏,鈴木 裕,森岡 恵美,鈴木 啓一,加藤 和雄,盧 尚建.培養脂肪細胞におけるヨード高含有卵の卵黄の脂肪蓄積抑制の効果.日本畜産学会報 87: 345-350
6. 鈴木 裕,中野 美智,芳賀 聡,中島 恵一,加藤 和雄,盧 尚建.2015.反芻動物におけるヘパトカインとしてのChemerinとANGPTL8の発現調節.栄養生理研究会報 59(2): 59-68
7. 鈴木 裕,北山 峻,山内 恵利,宋 相憲,加藤 和雄,盧 尚建.2013.反芻動物の糖脂質代謝系におけるChemerinの生理的作用機構と生産性との関連.栄養生理研究会報 57(1): 45-54
1. 板橋久雄(監)・小林泰男(編).2023.ルーメンの科学.農文協.第2章-1, 第3章-6.
Others
1. 鈴木 裕.2024.ルーメン細菌叢制御を目指した子ウシ唾液抗体の分泌機能の解明(Ⅱ).令和5年度食肉に関する助成研究調査成果報告書 42: 395-402.公益財団法人 伊藤記念財団
2. 鈴木 裕.2023.ルーメン細菌叢制御を目指した子ウシ唾液抗体の分泌機能の解明.令和4年度食肉に関する助成研究調査成果報告書 41: 461-466.公益財団法人 伊藤記念財団
3. 鈴木 裕.2018.ルーメンアシドーシス防除を目指した新規ルーメン幹細胞培養モデルの開発.平成29年度食肉に関する助成研究調査成果報告書 36: 411-417.公益財団法人 伊藤記念財団
4. 鈴木 啓一,加藤 和雄,紅 玉,鈴木 裕,盧 尚建,飯田 文子,小松 智彦.2015.メタボロミクス解析結果に基づく黒毛和種牛肉の美味しさに関わる指標の検証.平成27年度食肉に関する助成研究調査成果報告書 34: 61-66.公益財団法人 伊藤記念財団
5. 芳賀 聡,鈴木 裕,加藤 大地,加藤 和雄,盧 尚建.2015.反芻動物の生産に関する最近の研究動向(4) 泌乳生理機能と乳量制御.畜産の研究 69: 1005-1009.養賢堂
6. 鈴木 裕,加藤 大地,芳賀 聡,加藤 和雄,盧 尚建.2015.反芻動物の生産に関する最近の研究動向(3) 内分泌調節機能としての肝臓の機能.畜産の研究 69: 929-933.養賢堂
7. 加藤 大地,鈴木 裕,芳賀 聡,加藤 和雄,盧 尚建.反芻動物の生産に関する最近の研究動向(2) 反芻動物のルーメン発達と生産性との関連.畜産の研究 69: 861-865.養賢堂
Awards
1. Animal Science Journal Excellent Paper Award (Kato et al., 2016. Utilization of digital differential display to identify differentially expressed genes related to rumen development) .日本畜産学会.2020年3月
2. 奨励賞.第111号:肝臓由来内分泌因子に着目した反芻家畜の代謝調節機構に関する研究. 日本畜産学会.2017年3月
3. Animal Science Journal Excellent Paper Award (Suzuki et al., 2012. Chemerin analog regulates energy metabolism in sheep) .日本畜産学会.2016年3月